SU378763A1 - METHOD FOR DETERMINING TEMPERATURE CHANGES OF POISSON RATIO AND JUNG MODULE - Google Patents

Description

one

It is related to electrical acoustics and can be carried out using the IB technique with the optimal o6ipat6iOTKH radar-tracking Xishals.

The known methods for determining the temperature variations of the Poisson coefficient and the modulus for measuring the temperature of specimens of the parameter in the sipnal do not allow simultaneous determination of the temperature range of the Uig module and the coefficient nyaiccoiHH of one sample at a high frequency with sufficient accuracy.

According to the proposed method, with the aim of increasing the frequency and increasing the frequency range, they are the same (M (or the opposite changes of the sipnal delay time at the frequency corresponding to the maximum delay of the first mode and the frequency equal to 0.8 from the previous value, and determine the desired parameters by calculation.

The essence of the proposed method is as follows.

If in a plate of a single length, the spread is eto of the first wave of symmetrical Lamb waves, then the delay of the signal in it can be represented by the following expression;

- / f

(-. /),

2

where T - (Time delay signal; in - density; E - 1 Young modulus;

(, /) is a complex fumulation of Poisson’s ratio i and frequency /. The change in temperature leads to increments of the length and elastic elements of the plastics so that

F C, - f + St - 0.5 (t +),

where f, t, t, t- are, respectively, the temperature coefficients of the delay, modulus of Yunt, Poisson's ratio and linear expansion;

Ci and S are functions derived from the dispersion curves of the first Lamb mode.

Usually, the value of t is 1 is efficient, since its precise determination is not difficult. To find / and with known / for) Mvr values of f, obtained at two frequencies: at a frequency D "corresponding to the maximum delay of the first mode, and at a frequency of 0.8 /). The values of t and t are calculated by the formulas:

Г (0.8) - (1,0) -5g; Ci (0.8) + 0, l 34

, 2 (S-0.5) -C, (0.8) -Luga by measuring temperature measurements of 2C (0.8) (1.0) 0.2i (0.8) neny signal parameters, different

 ; / - / and gj Q; Then, in order to increase the accuracy and broadening of the frequency range, we measure ... .. -5 the changes in the sigma-ray delay time to the frequency corresponding to the method of determining temperature changes-0, 8 from this value, and according to their designations of the Poisson coefficient and moduli, the desired parameters are determined.

378763

mu leroy delays | mods, and a frequency equal to